Deck 14: Metabolic Diversity of Microorganisms

A) oxidation reactions.
B) reduction reactions.
C) both oxidation and reduction reactions.
D) neither oxidation nor reduction reactions.

A) bacteriochlorophylls and pigments they contain.
B) chlorophylls they can have and organic compounds they can produce.
C) light-harvesting complexes, electron donors, and organic compounds they produce.
D) unrelated taxa capable of photosynthesis.

A) is responsible for the fixation of CO₂ into cell material.
B) utilizes both NAD(P)H and ATP.
C) requires both ribulose bisphosphate carboxylase and phosphoribulokinase.
D) uses CO₂, NAD(P)H, and ATP to make biomass with ribulose bisphosphate carboxylase and phosphoribulokinase.

A) Additional electron acceptors, such as NADP⁺, will be required to oxidize oxygen and overcome the lost PSII process.
B) Anoxygenic photosynthesis only using photosystem I (PSI) could occur by using cyclic photophosphorylation and an alternative electron donor such as H₂S.
C) It will die from being unable to obtain energy for photosynthesis.
D) Photons will generate excessive reactive oxygen species and the cyanobacterium will die as a consequence.

A) purple Bacteria
B) chemolithotrophic Bacteria
C) cyanobacteria
D) anoxygenic Chloroflexus

A) contains the reverse citric acid cycle.
B) has a deficient Calvin cycle and accumulated CO₂.
C) is in a carboxylic acid rich environment and is storing excess quantities for potentially harsh conditions.
D) will use the Calvin cycle to convert the concentrated into biomass.

A) green bacteria / antenna pigments
B) green bacteria / chlorosomes
C) purple bacteria / antenna pigments
D) purple bacteria / chlorosomes

A) algae.
B) green sulfur bacteria.
C) most autotrophic organisms.
D) purple phototrophic bacteria.

A) iron (II)
B) iron (III)
C) magnesium
D) manganese

A) E
B) S
C) Q
D) Z

A) two bacteriochlorophyll a molecules
B) two bacteriochlorophyll b molecules
C) two quinones
D) two reaction centers

A) the red phycobiliprotein.
B) the blue phycobiliprotein.
C) a type of carotenoid.
D) a green carotenoid.

A) membrane-bound sac found in certain bacteria.
B) photosynthetic pigment found in some bacteria.
C) copper-containing protein in photosystem II that donates electrons to photosystem I.
D) blue-green bacterium known for its unusual photoreactive complex.

A) energy source.
B) carbon source.
C) oxygen requirements.
D) carbon and energy sources.

A) as accessory pigments
B) photoprotection
C) to produce singlet oxygen
D) to quench toxic oxygen species

A) hydrogen sulfide.
B) elemental sulfur.
C) sulfate.
D) thiosulfate.

A) proton motive force.
B) reduction.
C) electron transport.
D) energy flow.

A) Chlorobium uses the reverse citric acid cycle, and Chloroflexus uses the hydroxypropionate pathway.
B) Chlorobium uses the hydroxypropionate pathway, and Chloroflexus uses the reverse citric acid cycle.
C) both Chlorobium and Chloroflexus use the reverse citric acid cycle.
D) both Chlorobium and Chloroflexus use the hydroxypropionate pathway.

A) cyanobacteria
B) eukaryotic phototrophs
C) green bacteria
D) prochlorophytes

A) chlorophyll or bacteriochlorophyll.
B) carotenoids.
C) phycoerythrin.
D) phycocyanin.

A) Electrons from metal cofactors energize the electron transport chain and drive the proton motive force to activate ATP synthase.
B) Substrate-level phosphorylation of ADP occurs when coenzyme A is removed from acetyl-CoA.
C) It is made using substrate level phosphorylation and an ion motive force.
D) Acetyl CoA is produced from acetate and ATP is produced through substrate level phosphorylation.

A) alkaline conditions.
B) high H⁺ concentrations.
C) high oxygen content.
D) little or no light present.

A) Acetate and butyrate accumulation creates a deadly acidic environment, which acetone and butanol do not.
B) Acetate and butyrate are no longer needed for biosynthetic pathways.
C) Acetone and butanol serve as better sources for NAD(P)⁺ reduction.
D) Acetone and butanol production is favored for stability to store intracellular carbon sources for potential nutrient poor conditions.

A) The cells avoid producing transport energy waste to secrete the sulfur.
B) The byproduct serves as an electron reserve for subsequent oxidation.
C) Sulfur decreases the intracellular acidification for non-acid-tolerant sulfide oxidizers.
D) The byproduct can be used for other biosynthetic pathways that use sulfur, such as Rieske Fe-S proteins.

A) amino acid fermentation by clostridia.
B) secondary fermentation.
C) sulfur-oxidizing bacteria.
D) syntrophic carbohydrate metabolism.

A) An alternative carbon source such as methanol was used.
B) CO₂ is not a carbon source used by methanogens.
C) CO₂ was used as an electron donor but not as a carbon substrate.
D) Methanogenic Archaea containing carboxysomes likely made measuring small losses of CO₂ difficult to conclude.

A) ammonia
B) ammonium
C) ammonia and nitrate
D) ammonia and nitrite

A) acetogens
B) methanotrophs
C) methanogens
D) acetogens and methanogens

A) genes encoding reaction center and light-harvesting photocomplexes
B) genes encoding proteins involved in phycobiliprotein biosynthesis
C) genes encoding proteins involved in bacteriochlorophyll biosynthesis
D) genes encoding proteins involved in carotenoid biosynthesis

A) anaerobic fermentation
B) disproportionation
C) methylotrophy
D) syntrophy

A) hexose 2 lactate + 2 H⁺
B) HCOOH H₂ + CO₂
C) glucose lactate + ethanol + CO₂ + H⁺
D) fructose 3 acetate + 3 H⁺

A) Ammonium rather than ammonia would be used due to ammonia toxicity to other cellular processes within the anammoxosome.
B) It would require a different source for carbon assimilation.
C) Rates of anammox would be considerably slower due to a lack of localized metabolism.
D) Toxic products of the anammox reaction could kill the cell.

A) can circumvent substrate-level and oxidative phosphorylation.
B) makes insufficient energy to grow but enough for cellular maintenance to survive.
C) requires a second bacterium to cooperatively drive the gradient.
D) still requires another carbon substrate to provide a carbon source.

A) adenosine phosphosulfate reductase coupled with substrate-level phosphorylation.
B) electrons being transferred to cytochrome c prior to shuttling them into the electron transport chain.
C) identifying an alternative quinone, flavoprotein, or cytochrome.
D) quantifying the release of sulfate byproduct.

A) acetate
B) carbon monoxide
C) methane
D) methanol

A) lower / assimilative
B) lower / dissimilative
C) higher / assimilative
D) higher / dissimilative

A) CO₂.
B) coenzyme A.
C) NAD(P)H.
D) organic compound(s) formed.

A) high / thrive in such conditions by not competing with chemoorganotrophs
B) high / generate important reducing equivalents as byproducts for other microorganisms in the soil
C) low / do not occur in such habitats
D) low / will need a chemoorganotrophic way to grow as well

A) nitrate / sulfate
B) nitrate / sulfite
C) nitrite / sulfate
D) nitrite / sulfite

A) CH₂O (formaldehyde) / CO
B) CH₂O (formaldehyde) / CO₂
C) HCOO−(formate) / CO
D) HCOO−(formate) / CO₂

A) acetogens
B) anoxygenic hydrocarbon fermenters
C) methanogens
D) methylotrophs

A) Sulfate is toxic to these archaeans.
B) Having fewer metabolic capabilities decreases the archaeonʹs genome size and gives it flexibility to interact with other reducing bacteria, such as nitrate bacteria.
C) The archaeans are too rare to survive without the bacteria.
D) The methane-oxidizing Archaea are not capable of acquiring this metabolic capability.

A) fermentation
B) anoxygenic photosynthesis
C) anoxic ammonia oxidation
D) acetogenesis

A) 1 three-carbon compound and 1 four-carbon compound
B) 1 three-carbon compound and 2 two-carbon compounds
C) 2 three-carbon compounds and CO₂
D) 3 two-carbon compounds and CO₂